AI in Nanotechnology for Biomedical Use

Nanotechnology has been slowly treading into the field of biomedicine for almost a decade now. Because nanotechnology for biomedical usage is still a relatively newer technology surrounded by many ethical debates, its footsteps are a little slow and careful. So what is nanotechnology? As the name would suggest, it is the putting of nanotechnology to medicinal usage and that is where AI, aka artificial intelligence, comes to light.

You can put about a thousand nano-particles side by side in the cross-section of a singular hair and disseminate them into the bloodstream to be in motion with the same fluidity as a red blood cell. Many biomedical scientists and researchers have managed to apply nanotechnology productively. In 2016, a DNA nanorobot was created for targeted drug delivery in cancerous cells. The National Center for Nanoscience and Technology, Beijing, China recently created a bactericidal nanoparticle that carried an antibiotic and successfully suppressed a bacterial infection in mice.

However, the most remarkable innovation in this field was in 2017, when biomedical engineers designed and created small-scale locomotive robots mimicking the structure, mobility and durability of red-blood cells. These nanobots developed by AI architects exhibit the ability to swim, climb, roll, walk, jump over and crawl in between the liquid or solid terrains inside the human body. Scientists expect that with the creation of these nanobots, they will be able to freely circulate around the body, diagnose malfunctions, deliver drugs to the disease, and report back by lighting up while performing their drug delivery.

As amazing as that may sound, some find it equally invasive; hence, the ethical debates surrounding nanomedicine. However, taking a completely neutral stance, we will try to give the readers a brief overview of what Ai in nanotechnology for biomedical usage is all about, what strides it has made and where it stands now.

Ai in Nanotechnology for Biomedical Usage Methods

Owing to these characteristics, nano-particles have found their effective uses in the medicinal field. Some Ai in nanotechnology for biomedical usage methods includes the following:

This involves nano-particles that are constructed of immune-system-friendly materials, implanted with drugs and sent to the targeted areas of the body. Owing to their small size, they can effectively target only the areas that are disease-ridden, dysfunctional parts of the cells as opposed to the entire cells, or whole organs. This essentially means minimal side effects because it lowers healthy cell damage.

This can be demonstrated by the example of NCNST creating nano-robots that carried a blood-coagulating enzyme called Thrombin. These thrombin-carrying nano-particles were then sent to tumor cells, essentially cutting off tumor blood supply. Another example of drug delivery using nanoparticles is of CytImmune, a leading diagnostic company that used nanotechnology for precision-based delivery of chemotherapy drugs – it published the results of their first clinical trials, while the second one is underway. Many such methods of drug delivery are being used for cancer, heart diseases, mental diseases and even aging.

Regenerative Ai in Nanotechnology for Biomedical

According to the National Institutes of Health, the procedure encompassing regenerative involves “creating live, practicable tissues to repair or replace tissues or organ functions lost because of a slew of reasons, which may be chronic disease, increasing age or congenital defects.”

Just as nano-bots mimic the structure of red blood cells, they can mimic the function of autoimmune cells and antibodies to aid the natural healing process. Because the natural cellular interaction takes place at a micro-scale level, nanotechnology can make its uses known in multiple different ways. Some of these include regeneration of bone, skin, teeth, eye-tissue, nerve cells and cartilages. Ai is able to collect, direct, and modify regenerations.

You can read about the Ai in nanotechnology for biomedical usage based cell repair by in the following article; The Ideal Gene Delivery Vector: Chromalloytes, Cell Repair Nanorobots for Chromosome Repair Therapy. While such a powerful and innovative technology has its innumerable advantages in the medical field, it must be used within certain ethical perimeters for long-term applicability. Nano-technology brings with it many risks that need to be kept in mind by researchers. If you need help to identify and recruit senior executives or functional leaders in advanced medical devices, electronic health records, biopharma, or artificial intelligence technology, consider the experienced team at NextGen Global Executive Search.